Diffuse white matter injury (DWMI), a leading cause of neurodevelopmental disabilities in preterm infants, is characterized by reduced oligodendrocyte formation. Oligodendrocyte precursor cells (NG2-cells) are exposed to various extrinsic regulatory signals, including the neurotransmitter GABA. We investigated GABAergic signaling to cerebellar white matter NG2-cells in a mouse model of DWMI (chronic neonatal hypoxia). We found that hypoxia caused a loss of GABAA receptor-mediated synaptic input to NG2-cells, extensive proliferation of these cells and delayed oligodendrocyte maturation, leading to dysmyelination. Treatment of control mice with a GABAA receptor antagonist or deletion of the chloride-accumulating transporter NKCC1 mimicked the effects of hypoxia. Conversely, blockade of GABA catabolism or GABA uptake reduced NG2-cell numbers and increased the formation of mature oligodendrocytes both in control and hypoxic mice. Our results indicate that GABAergic signaling regulates NG2-cell differentiation and proliferation in vivo, and suggest that its perturbation is a key factor in DWMI.
Although the properties and trafficking of AMPA-type glutamate receptors (AMPARs) depend critically on associated transmembrane AMPAR regulatory proteins (TARPs) such as stargazin (γ-2), no TARP has been described that can specifically regulate the important class of calciumpermeable (CP-) AMPARs. We examined the stargazin-related protein γ-5, which is highly expressed in Bergmann glia, a cell type possessing only CP-AMPARs. γ-5 was previously thought not to be a TARP, and it has been widely used as a negative control. Here we find that, contrary to expectation, γ-5 acts as a TARP and serves this role in Bergmann glia. Whereas, γ-5 interacts with all AMPAR subunits, and modifies their behavior to varying extents, its main effect is to regulate the function of AMPAR subunit combinations that lack short-form subunits, which constitute predominantly CP-AMPARs. Our results suggest an important role γ-5 in regulating the functional contribution of CP-AMPARs.
Ionotropic glutamate receptors, which underlie a majority of excitatory synaptic transmission in the CNS, associate with transmembrane proteins that modify their intracellular trafficking and channel gating. Significant advances have been made in our understanding of AMPA-type glutamate receptor (AMPAR) regulation by transmembrane AMPAR regulatory proteins. Less is known about the functional influence of cornichons-unrelated AMPAR-interacting proteins, identified by proteomic analysis. Here we confirm that cornichon homologs 2 and 3 (CNIH-2 and CNIH-3), but not CNIH-1, slow the deactivation and desensitization of both GluA2-containing calciumimpermeable and GluA2-lacking calcium-permeable (CP) AMPARs expressed in tsA201 cells. CNIH-2 and -3 also enhanced the glutamate sensitivity, single-channel conductance, and calcium permeability of CP-AMPARs while decreasing their block by intracellular polyamines. We examined the potential effects of CNIHs on native AMPARs by recording from rat optic nerve oligodendrocyte precursor cells (OPCs), known to express a significant population of CP-AMPARs. These glial cells exhibited surface labeling with an anti-CNIH-2/3 antibody. Two features of their AMPAR-mediated currents-the relative efficacy of the partial agonist kainate (I KA /I Glu ratio 0.4) and a greater than fivefold potentiation of kainate responses by cyclothiazide-suggest AMPAR association with CNIHs. Additionally, overexpression of CNIH-3 in OPCs markedly slowed AMPAR desensitization. Together, our experiments support the view that CNIHs are capable of altering key properties of AMPARs and suggest that they may do so in glia.
Oligodendrocyte precursor cells (OPCs), a major glial cell type giving rise to myelinating oligodendrocytes in the CNS, express calcium-permeable (CP-) AMPARs. Although CP-AMPARs are important in OPC proliferation and neuron-glia signalling, they render OPCs susceptible to ischemic damage in early development. Here we identify factors controlling dynamic regulation of AMPAR subtypes in OPCs from rat optic nerve and mouse cerebellar cortex. We find that activation of group 1 mGluRs drives an increase in the proportion of CP-AMPARs, reflected in increased single-channel conductance and inward rectification. This plasticity requires elevation of intracellular calcium, utilizes PI3 kinase, PICK-1 and the JNK pathway. In white matter, neurons and astrocytes release both ATP and glutamate. Surprisingly, activation of purinergic receptors in OPCs decreases CP-AMPAR expression, suggesting a capacity for homeostatic regulation. Finally, we show that stargazin-related transmembrane AMPAR regulatory proteins, which are key for AMPAR surface expression in neurons, regulate CP-AMPAR plasticity in OPCs.
Graphical AbstractHighlights d Individual oligodendrocytes show bias for inhibitory axons in the neocortex d Interneuron sub-classes present different profiles of myelination d Class-specific myelin distribution patterns are set up from the onset of myelination SUMMARY Reciprocal communication between neurons and oligodendrocytes is essential for the generation and localization of myelin, a critical feature of the CNS. In the neocortex, individual oligodendrocytes can myelinate multiple axons; however, the neuronal origin of the myelinated axons has remained undefined and, while largely assumed to be from excitatory pyramidal neurons, it also includes inhibitory interneurons. This raises the question of whether individual oligodendrocytes display bias for the class of neurons that they myelinate. Here, we find that different classes of cortical interneurons show distinct patterns of myelin distribution starting from the onset of myelination, suggesting that oligodendrocytes can recognize the class identity of individual types of interneurons that they target. Notably, we show that some oligodendrocytes disproportionately myelinate the axons of inhibitory interneurons, whereas others primarily target excitatory axons or show no bias. These results point toward very specific interactions between oligodendrocytes and neurons and raise the interesting question of why myelination is differentially directed toward different neuron types.
The pathological mechanisms underlying neurological deficits observed in individuals born pre-maturely are not completely understood. A common form of injury in the pre-term population is periventricular white matter injury (PWMI), a pathology associated with impaired brain development. To mitigate or eliminate white matter injury, there is an urgent need to understand the pathological mechanism(s) involved on a neurobiological, structural and functional level. Recent clinical data suggests that a percentage of pre-mature infants experience relative hyperoxia. Using a hyperoxic model of pre-mature brain injury, we have previously demonstrated that neonatal hyperoxia exposure in the mouse disrupts development of the white matter (WM) by delaying the maturation of the oligodendroglial lineage. In the present study, we address the question of how hyperoxia-induced alterations in WM development affect overall WM integrity and axonal function. We show that neonatal hyperoxia causes ultra-structural changes, including i) myelination abnormalities (reduced myelin thickness and abnormal extra myelin loops) and ii) axonopathy (altered neurofilament phosphorylation, paranodal defects and changes in node of Ranvier number and structure). This disruption of axon-oligodendrocyte integrity results in the lasting impairment of conduction properties in the adult WM. Understanding the pathology of pre-mature PWMI injury will allow for the development of interventional strategies to preserve WM integrity and function.
Key points The hippocampal CA1 region is highly vulnerable to ischaemic stroke. Two forms of AMPA receptor (AMPAR) plasticity – an anoxic form of long‐term potentiation and a delayed increase in Ca2+‐permeable (CP) AMPARs – contribute to this susceptibility by increasing excitotoxicity.In CA1, the acid‐sensing ion channel 1a (ASIC1a) is known to facilitate LTP and contribute to ischaemic acidotoxicity.We have examined the role of ASIC1a in AMPAR ischaemic plasticity in organotypic hippocampal slice cultures exposed to oxygen glucose deprivation (a model of ischaemic stroke), and in hippocampal pyramidal neuron cultures exposed to acidosis.We find that ASIC1a activation promotes both forms of AMPAR plasticity and that neuroprotection, by inhibiting ASIC1a, circumvents any further benefit of blocking CP‐AMPARs.Our observations establish a new interaction between acidotoxicity and excitotoxicity, and provide insight into the role of ASIC1a and CP‐AMPARs in neurodegeneration. Specifically, we propose that ASIC1a activation drives certain post‐ischaemic forms of CP‐AMPAR plasticity. AbstractThe CA1 region of the hippocampus is particularly vulnerable to ischaemic damage. While NMDA receptors play a major role in excitotoxicity, it is thought to be exacerbated in this region by two forms of post‐ischaemic AMPA receptor (AMPAR) plasticity – namely, anoxic long‐term potentiation (a‐LTP), and a delayed increase in the prevalence of Ca2+‐permeable GluA2‐lacking AMPARs (CP‐AMPARs). The acid‐sensing ion channel 1a (ASIC1a), which is expressed in CA1 pyramidal neurons, is also known to contribute to post‐ischaemic neuronal death and to physiologically induced LTP. This raises the question does ASIC1a activation drive the post‐ischaemic forms of AMPAR plasticity in CA1 pyramidal neurons? We have tested this by examining organotypic hippocampal slice cultures (OHSCs) exposed to oxygen glucose deprivation (OGD), and dissociated cultures of hippocampal pyramidal neurons (HPNs) exposed to low pH (acidosis). We find that both a‐LTP and the delayed increase in the prevalence of CP‐AMPARs are dependent on ASIC1a activation during ischaemia. Indeed, acidosis alone is sufficient to induce the increase in CP‐AMPARs. We also find that inhibition of ASIC1a channels circumvents any potential neuroprotective benefit arising from block of CP‐AMPARs. By demonstrating that ASIC1a activation contributes to post‐ischaemic AMPAR plasticity, our results identify a functional interaction between acidotoxicity and excitotoxicity in hippocampal CA1 cells, and provide insight into the role of ASIC1a and CP‐AMPARs as potential drug targets for neuroprotection. We thus propose that ASIC1a activation can drive certain forms of CP‐AMPAR plasticity, and that inhibiting ASIC1a affords neuroprotection.
volume 12 | number 6 | June 2009 nature neuroscience e r r ata a n d co r r i g e n d u m Erratum: A dual leucine kinase-dependent axon self-destruction program promotes Wallerian degeneration In the version of this article initially published, the abbreviation DLK was omitted from the abstract. The second sentence of the abstract should be "We found that dual leucine kinase (DLK) promoted degeneration of severed axons in Drosophila and mice, and that its target, c-Jun N-terminal kinase, promoted degeneration locally in axons as they committed to degenerate". The error has been corrected in the HTML and PDF versions of the article.Erratum: A precise form of divisive suppression supports population coding in the primary visual cortex In the version of this article initially published, the gray curve in Figure 1j was shifted to the left. The corrected figure is shown below. The error has been corrected in the HTML and PDF versions of the article. In the version of this article initially published, the bar graphs in Figure 7c and 7d were misaligned. The error has been corrected in the HTML and PDF versions of the article.Corrigendum: Links from complex spikes to local plasticity and motor learning in the cerebellum of awake-behaving monkeys In the version of this article initially published, two citations were inadvertently omitted. To correct this, the following two sentences were added to the second paragraph of the introduction, following the sixth sentence. "One line of work has supported the theory by demonstrating that arm movement errors evoke complex spikes 51,52 and that subsequent learned changes in motor behavior are associated with suitable changes in simple spike responses 51 . This work demonstrates a strong correlation, but stops short of showing cause-and-effect links between individual complex spikes, changes in simple spikes and behavioral learning." Two references were also added to the reference list as follows:51. Gilbert, P.F. & Thach W.T. Purkinje cell activity during motor learning. Brain Res. 128, 309-328 (1977). 52. Ojakangas C.L & Ebner T.J. Purkinje cell complex and simple spike changes during a voluntary arm movement learning task in the monkey. J. Neurophysiol. 68, 2222Neurophysiol. 68, -2236Neurophysiol. 68, (1992.In addition, the second sentence of the abstract should read "Many elements of this hypothesis have been supported by prior experiments, and correlations have been found between complex spikes, simple-spike plasticity and behavior during the learning process." The errors have been corrected in the HTML and PDF versions of the article.
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